I remember once going to see [Srinivasa Ramanujan] when he was ill at Putney. I had ridden in taxi cab number 1729 and remarked that the number seemed to me rather a dull one, and that I hoped it was not an unfavorable omen. "No," he replied, "it is a very interesting number; it is the smallest number expressible as the sum of two cubes in two different ways." [G. H. Hardy as told in "1729 (number)"]

In "Math Wrath" Joseph Tartakovsky says about this feat, "So what? Give me two minutes and my calculator watch, and I'll do the same without exerting any little gray cells." I don't know how Mr. Tartakovsky would accomplish that proof on a calculator watch, but the following is my scheme function that enumerates numbers starting at 1 and stops when it finds a number that is expressable in two seperate ways by summing the cubes of two positive numbers. And it indeeds returns 1729.

There are two areas where I would appreciate suggestions for
improvement. One area is, being new to scheme, style and idiom. The other area is around the calculations. Sisc
does not return exact numbers for roots, even when they could be. For
example `(expt 27 1/3)`

yields 2.9999999999999996. But I do get exact
retults when cubing an exact number, `(expt 3 3)`

yields `27`

. My
solution was to get the exact floor of a cube root and then test
against the cube of the floor and the cube of the floor plus one,
counting as a match if either match. This solution seems messy and hard to reason about. Is there a more straightforward way?

```
; Find the Hardy-Ramanujan number, which is the smallest positive
; integer that is the sum of the cubes of two positivie integers in
; two seperate ways.
(define (hardy-ramanujan-number)
(let ((how-many-sum-of-2-positive-cubes
; while i^3 + 1 < n/1
; tmp := exact_floor(cube-root(n - i^3))
; if n = i^3 + tmp^3 or n = i^3 + (tmp + 1) ^3 then count := count + 1
; return count
(lambda (n)
(let ((cube (lambda (n) (expt n 3)))
(cube-root (lambda (n) (inexact->exact (expt n 1/3)))))
(let iter ((i 1) (count 0))
(if (> (+ (expt i 3) 1) (/ n 2))
count
(let* ((cube-i (cube i))
(tmp (floor (cube-root (- n cube-i)))))
(iter (+ i 1)
(+ count
(if (or (= n (+ cube-i (cube tmp)))
(= n (+ cube-i (cube (+ tmp 1)))))
1
0))))))))))
(let iter ((n 1))
(if (= (how-many-sum-of-2-positive-cubes n) 2)
n
(iter (+ 1 n))))))
```